CN101013644B - Plasma display panel and imaging device using the same - Google Patents

Abstract

A plasma display panel and an imaging device realize a high luminous efficiency, a long lifetime and stable driving. The plasma display panel uses a discharge-gas mixture containing at least Xe, Ne and He. A Xe proportion of the discharge-gas mixture is in a range of from 2% to 20%, a He proportion of the discharge-gas mixture is in a range of from 15% to 50%, the He proportion is greater than the Xe proportion, and a total pressure of the discharge-gas mixture is in a range of from 400 Torr to 550 Torr. A width of a voltage pulse to be applied to an electrode serving as an address electrode is 2 mus or less.

Description

The imaging device of plasma display panel and this plasma display panel of employing

It is 021305900 that the application of this division is based on application number, and the applying date is on 08 19th, 2002, and denomination of invention is divided an application for the Chinese patent application of " plasma display panel and adopt the imaging device of this plasma display panel ".

Technical field

The present invention relates to the imaging device of a kind of plasma display panel and this plasma display panel of employing.

Technical background

In recent years, plasma display panel (being called " PDP " at this) has caused great concern as a kind of pure flat, thin big display unit of section.That account for main flow at present is the coplanar discharge type PDP (becoming " exchanging coplanar discharge type PDP " at this) of AC driving.This interchange coplanar discharge type PDP is a kind of imaging device with the little discharge space (discharge cell) that is enclosed in a large number between a pair of glass substrate.

In PDP, gas (discharge gas) discharge contained in the discharge cell generates plasma, and the ultraviolet excited light-emitting material of these plasmas sends visible light, shows thereby form image.Also have a kind of light that directly comes from this plasma that utilizes to launch and the method for formation image demonstration.

Rare gas (the especially mist of Ne and Xe) mainly is used as discharge gas, becomes a kind of material in the plasm display device.Disclosed the mixture that utilizes He, Ne and three kinds of gases of Xe among the flat 6-342631 of Japanese Patent Application Publication special permission communique No. (open) on December 13rd, 1994.Wherein: the relative volume of He and Ne is 1.5% to 10% than the scope that is selected from 6/4 to 9/1 and selected Xe accounts for the scope of discharge gas cumulative volume.But this wherein has a problem, that is: excessive He can shorten the life-span of display unit.Disclosed a kind of technology among the Japanese Patent Application Publication special permission communique No.2000-67758 (open) on March 3rd, 2000, promptly control crosstalking between neighboring discharge cells, thereby increase the driving margin (drive margin) of sustaining voltage by the mixture that utilizes He, Ne, these three kinds of gases of Xe.Japanese Patent Application Publication special permission communique No. is flat-disclosed a kind of like this technology among the 11-103431 (open) on April 13rd, 1999, promptly utilize He, Ne, three kinds of admixture of gas of Xe and wherein the concentration of He and Xe equate, obtain the quality that the life-span is long, voltage output is stable and brightness is suitable.At N.Uemura, et al. " Kinetic Model of the VUVProduction in AC-PDPs as Studied by Time-resolved EmissionSpectroscopy ", Proceedings of IDW ' 00 (The7 ^ThInternational DisplayWorkshops, pp.639-642 (2000)) reported in and can utilize He, Ne, three kinds of admixture of gas of Xe to improve to produce ultraviolet efficient.

In the PDP evolution, need to improve luminous efficiency (lm/W).Luminous efficiency is definite like this: at first with brightness value (perhaps luminosity) (cd/m ²) encourage unit are to obtain the electrical power (W/m of above-mentioned brightness value divided by being used to ²), then utilize from light source observed by detection system right solid angle (surface of sphere) revise resulting ratio and determine.Because discharge gas can greatly influence ultraviolet generation, so its set point is very important for improving luminous efficiency.The state of plasma depends on the composition of discharge gas and pressure to a great extent and changes, and therefore luminous efficiency also changes a lot.Yet in the practical plasma scope process of development, plasma scope should synthetically have excellent performance with the luminous efficiency aspect of improving in other respects.If, then may make its lost of life, and may occur driving unstable for improving composition and the pressure that luminous efficiency changes discharge gas.In addition, in actual applications, wish that very its definition height, brightness height, cost are low etc.Therefore, in the practical plasma scope process of development, on the basis of the composition of considering discharge gas and pressure, be necessary to consider other conditions (drive condition, cost etc.).

Summary of the invention

The invention provides and a kind ofly can improve luminous efficiency, guarantee its long-life and drive stable PDP.And, PDP of the present invention can make high brightness, high definition and cheaply display unit become possibility.

For overcoming the above problems the selection that feature of the present invention comprises discharge gas component and total pressure and writes voltage pulsewidth etc.These features help to improve luminous efficiency, guarantee the long-life and reduce to drive unsteadiness.

According to an aspect of the present invention, provide a kind of plasma display panel, comprising: discharge sustaining electrode is right; Towards described discharge sustaining electrode to and the addressing electrode established; Discharge space between described discharge sustaining electrode pair and described addressing electrode; Be filled with the discharge mist that contains Xe, Ne, He at least in the described discharge space; Thereby be used for applying potential pulse and produce the circuit of writing discharge at described discharge space to described addressing electrode; Wherein: the ratio of Xe is in the 2%-20% scope in the described discharge mist; The ratio of He is in the 15%-50% scope in the described discharge mist; The ratio of described He is greater than the ratio of described Xe; The stagnation pressure of described discharge mist is 400 torrs-550 torrs; And the width of described potential pulse is less than or equal to 2 μ s.

According to another aspect of the present invention, a kind of imaging device is provided, comprise plasma display panel and the drive circuit that is used to drive described plasma display panel, contain a control circuit in the described drive circuit at least, described plasma display panel comprises: discharge sustaining electrode is right; Towards described discharge sustaining electrode to and the addressing electrode established; Discharge space between described discharge sustaining electrode pair and described addressing electrode; Be filled with the discharge mist that contains Xe, Ne, He at least in the described discharge space; Thereby be used for applying potential pulse and produce the circuit of writing discharge at described discharge space to described addressing electrode; Wherein: the ratio of Xe is in the 2%-20% scope in the described discharge mist; The ratio of He is in the 15%-50% scope in the described discharge mist; The ratio of described He is greater than the ratio of described Xe; The stagnation pressure of described discharge mist is 400 torrs-550 torrs; And the width of described potential pulse is less than or equal to 2 μ s.

Among the present invention, the discharge mist that (1) is adopted contains Ne, Xe, three kinds of compositions of He at least.The ratio of component of this discharge mist of following selection, the pressure of this discharge mist and be used to the pulsewidth writing-discharge.

The condition of this discharge mist is as follows:

(2) proportion that accounts for of Xe is 2% to 20%; The proportion that He accounts for is 15% to 50%; Wherein the ratio of (4) He is greater than the ratio of Xe; (5) stagnation pressure of this discharge mist is in 400 torr to 550 torr scopes.

And the voltage pulse width that (6) impose on addressing electrode (address electrode) is less than or equal to 2 μ s.

In addition, if construct in such a way, then the present invention will be more practical.

In the second embodiment of the present invention, the discharge mist contains the ratio of the ratio of the He of Xe, 15% to 50% proportion of 2% to 14% proportion and He greater than Xe; The stagnation pressure of this discharge mist is in 400 torr to 550 torr scopes; The voltage pulse width that imposes on addressing electrode is less than or equal to 2 μ s.This embodiment can obtain to be more conducive to practical PDP.If the ratio of selected Xe greater than 14%, then can make continuous discharge voltage increase.

In the 3rd embodiment of the present invention, the discharge mist contains the ratio of the ratio of the He of Xe, 15% to 50% proportion of 6% to 14% proportion and He greater than Xe; The stagnation pressure of this discharge mist is in 400 torr to 550 torr scopes; The voltage pulse width that imposes on addressing electrode is less than or equal to 2 μ s.This embodiment can obtain to have the PDP of special high brightness and excellent luminous efficiency.

In the 4th embodiment of the present invention, the discharge mist contains the ratio of the ratio of the He of Xe, 15% to 50% proportion of 6% to 12% proportion and He greater than Xe; The stagnation pressure of this discharge mist is in 400 torr to 550 torr scopes; The voltage pulse width that imposes on addressing electrode is less than or equal to 2 μ s.For the aforementioned proportion of Xe, the benefit that the ratio of above-mentioned He is brought is remarkable especially, thereby and has effectively improved luminous efficiency and obtained high-brightness PDP.

Certainly, PDP of the present invention can provide the imaging device with above-mentioned characteristic.

Description of drawings

In the accompanying drawing, in all figure, all use identical Reference numeral to represent identical parts, wherein:

Fig. 1 illustrates the decomposition diagram of a part of the applied PDP of the present invention;

Fig. 2 signal is from the cross sectional representation of the cross-sectional structure of Fig. 1 direction D2 direction major part that watch, PDP shown in Figure 1, and illustrated a discharge cell;

Fig. 3 illustrates the cross sectional representation of motion of the charged particle (positive and negative particle) in the plasma 10 shown in Figure 2;

Fig. 4 A-4C is a time diagram, and each all represents to be used for the course of work in the tv field period of display image on PDP;

Fig. 5 is illustrated in the three components discharge mist that utilizes various Ne, Xe, He ratio among each embodiment and the curve chart of the luminous efficiency measurement result that obtains;

Fig. 6 is illustrated in the three components discharges mist that utilizes various Ne, Xe, He ratio among each embodiment and the measured value of the improvement rate characteristic of the luminous efficiency that obtains and the curve chart of Xe ratio;

Fig. 7 is illustrated in the three components discharges mist that utilizes various Ne, Xe, He ratio among each embodiment and the measured value of the improvement rate characteristic of the luminous efficiency that obtains and the curve chart of He ratio;

The change curve of continuous discharge voltage when Fig. 8 represents to change the ratio of Xe;

The brightness conservation rate was with the change curve of operating time when Fig. 9 represented to change the ratio of He;

Figure 10 represents the graph of relation between the rate of change of He ratio and brightness conservation rate;

Figure 11 represents the curve chart of the measurement result of resulting brightness conservation rate and luminous efficiency when changing the discharge mist stagnation pressure contain Ne, Xe, three kinds of components of He;

Figure 12 represents to be used to guarantee the stable Study on Conditions result curve figure that writes discharge (write-discharge) when writing voltage (write-voltage) and containing He ratio in the discharge mist of Ne, Xe, three kinds of components of He when changing;

Figure 13 is provided by the block diagram of the example of a kind of imaging system of being provided by PDP of the present invention.

Embodiment

The basic structure and the course of work

Exchanging coplanar discharge type PDP is a kind of imaging device with the fine discharge space (discharge cell) that is enclosed in a large number between a pair of glass substrate.

Below in conjunction with accompanying drawing embodiment is described.In institute's drawings attached, all use identical Reference numeral to represent corresponding or intimate parts or part, and omit being repeated in this description them.

Fig. 1 is a decomposition diagram of representing the part-structure of a kind of typical interchange coplanar discharge type PDP by way of example.PDP shown in Figure 1 has front panel 21 and rear board 28, and they are all made by glass, and connects and be integral.This embodiment is a kind of reflection-type PDP, forms the fluorescence coating 32 of red (R), green (G) and blue (B) look fluorescent material in the back on the plate 28.In front plate 21 on the surface of rear board 28, have many discharge sustaining electrodes (being called " show electrode " sometimes) to being arranged in parallel with specific interval.Described many each in the discharge sustaining electrode are to all comprising an interconnective transparency electrode (after this being referred to as the X electrode) (22-1,22-1, ...) and one independently transparency electrode (after this being referred to as Y electrode or scan electrode) (23-1,23-2 ...).For increasing the conductivity of these transparent X, Y electrode, at X electrode (22-1,22-2 ...) and Y electrode (23-2,23-2, ...) last opaque X bus electrode (bus the electrode) (24-1 that covers, 24-2 ...) and opaque Y bus electrode (25-1,25-2, ...), they extend along the direction of arrow D2 indication shown in Figure 1 respectively.

For AC driving, the X electrode (22-1,22-2 ... .), the Y electrode (23-1,23-2 ...), the X bus electrode (24-1,24-2 ...) and the Y bus electrode (25-1,25-2 ...) all with discharge insulation.Specifically, each all applies a layer insulating 26 these electrodes, and this insulating barrier 26 is generally made by low-melting glass, and covers with a diaphragm 27.

The surface towards front panel 21 of plate 28 is provided with addressing electrode 29 (after this being called " A electrode ") in the back, it extends along arrow D1 direction shown in Figure 1, and the X electrode (22-1 that forms on A electrode and the front panel 21,22-1, ...) and the Y electrode (23-1,23-2 ...) separate, and, on the A electrode, apply a layer insulating 30 along direction extension perpendicular to above-mentioned X electrode and Y electrode.

On insulating barrier 30, be provided with ridge 31, be used to make the A electrode to be spaced from each other, thereby avoid the expansion (limiting a region of discharge therefrom) of discharging.In some cases, be provided with the ridge that extends along arrow D2 direction make X and Y discharge sustaining electrode between be spaced from each other.

On the respective groove surface of 31 formation of ridge, apply the fluorescence coating 32 of rubescent, the green and blue streak of strip in turn.

Fig. 2 is the cross sectional representation of the major part of the PDP that watches from arrow D2 direction shown in Figure 1, and has illustrated a discharge cell as the minimum image element.Among Fig. 2, dot the border of discharge cell.The discharge space of the discharge gas that is used to produce plasma is filled in Reference numeral 33 expression therebetween.When applying voltage between electrode, discharge gas ionization then produces plasma 10.Fig. 2 signal be cross sectional representation when producing the situation of plasma 10.With with Fig. 1 in used same reference numerals come corresponding component in the presentation graphs 2.From the ultraviolet ray excited fluorescent material 32 of plasma 10 and emission light, the light that is sent by this fluorescent material 32 passes front panel 21, thereby, the light combination of sending by each discharge cell and produce image and show.

Fig. 3 represents the motion schematic diagram of charged particle in the plasma 10 shown in Figure 2 (plus or minus particle).The negative particle (for example electronics) of Reference numeral 3 expressions, Reference numeral 4 expression positive corpusc(u)les (for example cation), the positive wall electric charge of Reference numeral 5 expressions, the negative wall electric charge of Reference numeral 6 expressions.Fig. 3 represents the state of charge sometime in the PDP course of work, and CHARGE DISTRIBUTION does not wherein have special implication.

Fig. 3 illustrates a kind ofly to apply corresponding positive voltage for A electrode 29 and X electrode 22-1 to begin the state that discharges, discharge and stop thereafter by applying negative voltage for Y electrode 32-1 by way of example.Consequently, form wall electric charge (being called " writing "), helped between Y electrode 23-1 and X electrode 22-1, to start discharge.Under this state,, then in the interelectrode discharge space of X, Y, will produce discharge via insulating barrier 26 (with diaphragm 27) if between Y electrode 23-1 and X electrode 22-1, apply suitable reverse voltage.After above-mentioned discharge stops, if the voltage reversal that is applied between Y electrode 23-1 and X electrode 22-1 then produces the discharge of another time again.This discharge process can be by constantly producing the polarity of voltage that is applied between X, Y electrode 22-1,23-1 oppositely and continuously.This just is called continuous discharge.

In the continuous discharge process, the easy degree that produces discharge is subjected to charged particle floating in this discharge space sometimes and is excited the influence of neutral particle (mainly being to be in metastable long-lived particle).Above-mentioned charged particle and be excited neutral particle and made starting particle (priming particle) by general designation sometimes.

Fig. 4 A-4C is the time diagram that is used for illustrating on PDP shown in Figure 1 the course of work of a TV field duration (TV field period) that shows that image is required.In the time diagram shown in Fig. 4 A, shown in (I), TV field duration 40 is divided into 8 son 41-48 that have different mutually greater than one light emitting times amount.Each gray scale is represented by the combination of one or more light emission field of selecting from above-mentioned 8 son 41-48.Shown in figure (II), what each son field had all that a replacement discharge cycle 49, one be used for determining Optical Transmit Unit writes discharge cycle 50 and a continuous discharge cycle 51.

Fig. 4 B is illustrated in writing shown in Fig. 4 A imposes on A electrode, X electrode and Y electrode in the discharge cycle 50 potential pulse shape (voltage pulse profile).Potential pulse shape 52 is the voltage waveforms that put on an A electrode in writing discharge cycle 50, potential pulse shape 53 is the voltage waveforms that put on the X electrode, potential pulse shape 54 and 55 is the voltage waveforms that put on i and (i+1) individual Y electrode respectively, and above-mentioned voltage is used V0, V1 and V2 (v) expression respectively.Among Fig. 4 B, the voltage pulsewidth that puts on the A electrode is represented with τ a.In Fig. 4 B, when applying scanning impulse 56 for i Y electrode, in the unit of i Y electrode and A electrode 29 intersections, discharge is write in generation.But,,, can not write discharge even apply scanning impulse 56 for i Y electrode if A electrode 29 is in earth potential (GND) yet.Like this, apply scanning impulse 56 in writing discharge cycle 50, for a Y electrode, then synchronous with this scanning impulse, apply voltage V0 for the A electrode 29 of the unit that will make it to produce light, and make the A electrode of other unit that do not need to produce light be made as earth potential.In writing the discharge cell of discharge, on covered dielectric layer and protective layer on the Y electrode, will produce electric charge because of writing discharge.Writing under the electric field action that discharge produces, can carry out the switch control of continuous discharge, these characteristics will be described in the back.In other words, produce the discharge cell of writing discharge and be used as luminescence unit, and remaining unit is as dark unit.

Fig. 4 C represents to put on the potential pulse of all X electrodes and Y electrode, and these electrodes serve as the discharge sustaining electrode in the continuous discharge cycle shown in Fig. 4 A 51.Potential pulse shape 58 puts on the X electrode, and potential pulse shape 59 puts on the Y electrode.The potential pulse V3 (V) of identical polar alternately imposes on X electrode and Y electrode, and like this, the interelectrode polarity of voltage of X electrode and Y is constantly reverse.The discharge that is produced in X electrode and the interelectrode discharge gas of Y by these potential pulses is called as continuous discharge.This continuous discharge is a pulsed, and alternating polarity changes.

The screen diagonal-size of existing PDP can have 32 inches, 42 inches and 60 inches.The discharging gap of this large scale PDP is usually in the 50-150 mu m range.The present invention can be used for this traditional PDP fully.

Above, the basic PDP structure that the present invention is suitable for has been described by way of example.Below based on above-mentioned basic PDP structure, describe the present invention in detail by embodiments of the invention.

Below with reference to the result shown in Fig. 5-7 the present invention is described.Carry out the measurement of luminous efficiency (lm/W) by the composition that utilizes above-mentioned basic PDP structure and Ne, Xe, three kinds of admixture of gas of He are charged into discharge space 33 and change this discharge mist.In this embodiment, the discharge mist comprises Ne, Xe, He, but also can contain a spot of gaseous impurity sometimes in this discharge mist.But even in this case, the present invention also can guarantee its characteristic.

Above-mentioned measurement is obtained by 35 kinds of ratio combinations of Xe, He, Ne, and wherein the ratio of Xe is 2%, 4%, 6%, 8%, 12%, 14% and 20, and the ratio of He is 0%, 10%, 15%, 30% and 50%, and remaining gas is Ne.The total pressure of each combination all is made as 500 torrs in these 35 kinds of ratio combinations.Do not point out the ratio of Ne among Fig. 5-7, they are residual componentss of above-mentioned composition.

The gas ratio of admixture of gas can be determined and measure in the following manner.

The ratio of the component α of discharge mist is determined by following mode:

The ratio of component α=N α/Nt............ (1),

Wherein: the particle of component α (atom or molecule) quantity in the discharge mist of N α=unit volume, for example represent with atom/cubic meter or molecule/cubic meter;

All particles in the discharge mist of Nt=unit volume (atom or molecule) quantity is for example represented with atom/cubic meter or molecule/cubic meter.

Component alpha proportion defined above can be rewritten and measure with following form according to physical law.

The ratio of component α=P α/Pt........... (2)

Wherein: the dividing potential drop of the gas component α of P α=discharge mist;

The stagnation pressure of Pt=discharge mist.

For example, the dividing potential drop of gas and stagnation pressure can be represented with torr.Stagnation pressure can be measured by Pressure gauge.For example, can form dividing potential drop and the stagnation pressure that gas is measured each gas component in the discharge mist by analyzing with mass spectrometer.

Learn from knowing as Fig. 5: luminous efficiency improves along with the increase of Xe ratio.But if the ratio of Xe surpasses 20%, if do not increase continuous discharge voltage significantly then PDP can not be driven, the back will make an explanation to this.So use Xe content is unpractiaca greater than 20% discharge mixture.

Fig. 8 is the curve between continuous discharge voltage V3 and Xe content ratio.Ratio at Xe surpasses at 20% o'clock, and continuous discharge voltage will significantly increase.So, when the Xe ratio surpasses 20%, have practicality hardly.On the other hand, if the ratio of Xe less than 2%, then luminous efficiency itself becomes too low, and is also impracticable.Yet the ratio that the curve of Fig. 8 is made as 500 torrs and He with the stagnation pressure of discharge mist is 0% to obtain, even He is added the discharge mist, its continuous discharge voltage V3 much variations can not take place yet, and depends primarily on the ratio of Xe.Therefore, according to other conditions of the present invention, the ratio of Xe is preferably in the 2%-20% scope.

This shows that from luminous efficiency and continuous discharge voltage, the ratio of Xe is preferably in the 2%-20% scope.

Turn one's head Fig. 5 now, the fiducial value that is used to estimate the raising of luminous efficiency is made as the luminous efficiency of the discharge mist that contains 0% He (Ne-Xe binary system).And for various Xe ratios, the ratio of luminous efficiency and each fiducial value is that the He with the ratio 10%, 15%, 30%, 50% of He is that calculation of parameter draws.In this manual, the ratio that is calculated is represented with percentage, is called as " the raising rate of luminous efficiency ".Fig. 6 represents " the raising degree of luminous efficiency ", and it as ordinate, and is made abscissa with Xe content.Fig. 7 represents " the raising degree of luminous efficiency ", and it as ordinate, and is made abscissa with He content.

From Fig. 6 obviously as seen, He ratio luminous efficiency in the 15%-50% scope improves greatly.In other words, when the ratio of Xe is in the 2%-20% scope, because the additional proportion scope makes luminous efficiency further improve at the He of 15%-50% gas in the discharge mist.

But as mentioned above, if the ratio of Xe increases, then continuous discharge voltage also need increase.In addition, clearly visible from Fig. 5: the raising degree of luminous efficiency increases along with the increase of Xe content, is to tend to saturated at 20% o'clock up to the ratio of Xe.Therefore, from continuous discharge voltage and luminous efficiency raising degree, we can say that the ratio that the practical preferred gas of discharge mist consists of He accounts for 15%-50%, the ratio of Xe accounts for 2%-14%.

In above-mentioned preferred gas was formed, if especially the ratio of Xe is elected as more than or equal to 6%, then (although not shown among Fig. 6, brightness peak surpassed 1000cd/m to the absolute value of the luminous efficiency that is obtained more than or equal to 1.1lm/W ²).Therefore, the discharge mist that wherein contains the He of the Xe of 6%-14% and 15%-50% can obtain to have the PDP of high brightness and high-luminous-efficiency.

And, from Fig. 7, obviously as seen, depend on the ratio of Xe by the influence degree of the He generation that is added.When the ratio of Xe was in the 6%-12% scope, it was especially effective to add He.Therefore, when PDP utilizes the discharge mist of Xe of the He contain 15%-50% and 6%-12%, under the effect of He gas, can obtain the high-brightness PDP that luminous efficiency is greatly improved.

And, aspect the ratio of He and Xe,, can see the following fact by analysis to Fig. 6.As can be seen, be 30% to compare with the He ratio with 50% luminous efficiency, the ratio of Xe is 20%, the luminous efficiency of the ratio 15% of He sharply descends.And as can be seen, the He ratio for 10%, Xe ratio are increased at 14%, 20% o'clock from 12%, and luminous efficiency sharply descends, although the He of 10% content is seldom effective.In brief, when He ratio during greater than the Xe ratio, the effect that adds He in the discharge mist is significant.Therefore, in the situation that adopts He, Xe combination, the ratio of selection He is very important greater than the ratio of Xe.

Above-mentioned result can explain with following model.The reason that improves luminous efficiency because of the adding of He is: the He that is added has increased and has produced ultraviolet branch order transition to excitation state Xe (cascade transition).For example, at " Proceedings of IDW ' 00 (The7 ^ThInternational Display Workshops), P.639 (2000) " in reported this classification transition process itself.Increase the quantity of excited atom in the branch order transition initial state with the bump transition (impact transition) of He, thereby increased the branch order transition.So, when He atomic quantity during greater than certain value, perhaps when the He atomic quantity greater than the Xe atomic quantity, in other words, be exactly that the effect of adding He is more remarkable when the ratio of He during greater than the ratio of Xe.

The effect that increases He with respect to the Xe ratio is similar to above-mentioned situation, and stagnation pressure wherein is 400 and 500 torrs.More specifically, under above-mentioned stagnation pressure, when adding content was the He of 15%-50% scope among the Xe in content is the 2%-20% scope, the effect of He had improved luminous efficiency.And from the raising degree of continuous discharge voltage and luminous efficiency, the discharge mist of He that contains the Xe of 2%-14% and 15%-50% is more practical.By the He of the Xe of 6%-14% and 15%-50% mix mutually and the discharge mist PDP that can obtain to have high brightness very and excellent luminous efficiency.In addition, if the discharge gas that is adopted consists of the Xe of 6%-12% and the He of 15%-50%, wherein the effect of the He that is added particularly strengthens, thereby can obtain the PDP of high brightness.When the ratio of He during greater than Xe, the effect that adds He is very remarkable.

Following conclusion is drawn by the foregoing description.

The ratio that adds the He of 15%-50% and He in the discharge mist of the Xe that contains the 2%-20% ratio is during greater than the ratio of Xe, and the effect of He makes luminous efficiency be improved.

From discharge sustain voltage and luminous efficiency raising degree, contain the He of the Xe of 2%-14% ratio and 15%-50% and wherein the ratio of He form more practical greater than the mist of the ratio of Xe.

In addition, by utilization contain the He of the Xe of 6%-14% ratio and 15%-50% and wherein the ratio of He greater than the discharge mist of the ratio of Xe, the PDP that can obtain to have special high brightness and excellent luminous efficiency.

And, containing the He of the Xe of 6%-12% ratio and 15%-50% and wherein the ratio of He is greater than the discharge mist of the ratio of Xe by utilization, luminous efficiency can significantly improve because of the effect of He, and can obtain the PDP of high brightness.

The life-span of PDP will be discussed below.Can improve luminous efficiency by adding He, if can cause the problem of the lost of life but the He that adds is excessive.Life-span be utilize the PDP running hours one long-time in the relative value that reduces in time of brightness assess.Specifically, PDP is set as 1.0 at the work brightness value in zero moment, and the brightness relative value after zero moment is represented with the conservation rate of brightness.Usually, should guarantee 20,000-30,000 hour life-span, but since the brightness conservation rate took place after 600 hours change can utilize about 600 hours measured data of operation and easily draw, so only done to moving about 600 hours assessment.

Fig. 9 and 10 expressions life appraisal result of the present invention.Fig. 9 represents that to containing proportional be that 8% Xe and ratio are respectively the measured brightness conservation rate of various discharge mists that 0%, 15%, 30%, 50% and 60% He and stagnation pressure remain on 500 torrs.Subsequently, the fiducial value that is used to estimate the brightness conservation rate is decided to be the measured brightness value of discharge mist (Ne-Xe binary system) that contains 0% He, and calculates brightness conservation rate measured in the discharge mist that contains 0%, 15%, 30%, 50% and 60% He respectively and the ratio of each fiducial value.In this manual, the described ratio calculated of representing with percentage is called as " rate of change of brightness conservation rate ", and in Figure 10 it is made ordinate, and makes abscissa with the ratio of He, with the passage time be parameter.

Clearly visible from Fig. 9, the brightness conservation rate reduces in time.The reduction degree of brightness conservation rate reduces along with the increase of He content.Among Figure 10, with the He ratio is that the reduction of the brightness conservation rate of zero discharge mist is compared, until the content of He is increased to the reduction degree of 50% o'clock brightness conservation rate also is not so big, but when selected He ratio was equal to or greater than 60%, the brightness conservation rate just sharply reduced.In other words, if the ratio of He surpasses 50%, then the life-span of PDP will shorten dramatically, thereby reduce practical value.

Clear as can be known from above real examination: as to be restricted to 50% by ratio, just can to guarantee the life-span of PDP well He.The He that contains with good grounds ratio of the present invention just can guarantee the described performance relevant with the life-span, the i.e. rate of change of brightness conservation rate with the discharge mist of Xe.

In an embodiment of the present invention, the stagnation pressure of discharge mist that contains the He of 62% Ne, 8% Xe and 30% by change comes the variation in luminous efficiency and life-span is studied.Estimate its life-span with the brightness conservation rate of operation after 672 hours.Figure 11 has represented above-mentioned experimental result.Abscissa is represented the stagnation pressure of mist, represents the life-span, represents luminous efficiency with hollow square with filled circles on the ordinate.Clearly visible from Figure 11: do not changing under the situation that mist forms, when the stagnation pressure of mist when 350 torrs are increased to 550 torrs, luminous efficiency is improved.But even stagnation pressure is increased to 600 torrs from 550 torrs, luminous efficiency also no longer improves.And because the stagnation pressure of 600 torrs is too high, so the difference between stagnation pressure and atmospheric pressure becomes very little, thereby the panel of PDP may be at low atmospheric pressure place for example on the aircraft or impaired on the plateau, and this is because pressure becomes also higher than atmospheric pressure in the panel.In addition, when stagnation pressure is elected as when being equal to or less than 350 torrs, the luminous efficiency step-down, and brightness conservation rate (life-span) sharply reduces.If stagnation pressure is too low, ion with the collision of other neutral atom before the mean free path moved increase, institute is so that play diaphragm or the lip-deep ion kinetic energy increase of fluorescence at PDP,, thus brightness conservation rate (life-span) reduces.Therefore, for the discharge mist that contains He, best stagnation pressure scope is the 400-550 torr.

The discharge mist that contains 66% Ne, 4% Xe and 30% He by utilization carries out similar experiment with the another kind of discharge mist that contains 58% Ne, 14% Xe and 30% He, and still can find: best stagnation pressure scope is 400 torrs-550 torrs.

The stability of subsequent discussion discharge.Have a problem like this when assessment discharge mist composition, their stagnation pressure and life-span: discharge can become unstable when the ratio of Xe increases.Especially, when only being a column unit set on the D2 direction shown in Figure 1 when luminous, on the PDP display panel tangible scintillation can appear.The back of scrutinizing to above-mentioned phenomenon is found: writing in the discharge cycle 50 in Fig. 4 A shown in (II), after applying the voltage of potential pulse shape 52, writing discharge and lagging behind, consequently to A electrode 29, write potential pulse even applied for A electrode 29, also can not discharge sometimes.

It is believed that: the lagging reasons of writing discharge is, because the increase of Xe ratio, quickened to float on the minimizing of starting particle in the discharge space (charged particle and be excited neutral particle) quantity.More specifically, clearly visible from Fig. 1, on D2 direction shown in Figure 1 only in the luminous situation of a set column unit, because luminescence unit separated each other by ridge 31, so luminescence unit is not subjected to the influence of the starting particle that is beneficial to discharge in the adjacent cells.The reason that above-mentioned phenomenon occurs especially is: in the Xe atom that metastable state is excited, be excited XeO forming with other Xe atom generation three-body collision ₂The quantity of Xe atom of being excited that thereby molecule is luminous, disappear at last increases along with the increase of Xe ratio.

Three kinds of following methods can be used as eliminates the above-mentioned countermeasure of writing discharge lag in the discharge process:

(1) increases the voltage V0 that writes discharge, promptly increase the electric field strength in the discharge space;

(2) increase the concentration of He, that is: increase the ratio of He, increasing the mobility of cation in the discharge mist, thereby quicken the formation of discharge;

(3) increase the voltage pulsewidth τ that imposes on the A electrode of widening _a, that is, and with pulsewidth τ _aIncrease by one and corresponding time of discharge lag time.

Figure 12 represents to study and writes the result that discharge condition obtains, wherein: only have that to be located among Fig. 1 the column unit on the D2 direction luminous, and the concentration of writing discharge voltage (writing voltage) and He is changing all.In this case, the ratio of Xe is 12%, and stagnation pressure is 500 torrs.Among Figure 12, open circles is represented the common discharge scenario of writing, and x represents the unusual discharge scenario of writing.At this moment, impose on the voltage pulse width τ of A electrode _aBe 2 μ s.Shown in Fig. 4 A, the length of writing discharge cycle 50 is limited, and must carry out the discharge of writing of specific quantity in this writes discharge cycle 50.Increase brightness if desired, then need to increase the quantity of continuous discharge potential pulse, consequently: must write discharge cycle by shortening and extend the continuous discharge cycle.Write discharge cycle if shortened, just need reduce pulsewidth τ _aAnd, improve display resolution if desired, just must increase the quantity of discharge cell, this will need to increase writes discharge cycle.Then, must reduce pulsewidth τ _a, especially, it must be equal to or less than 2 μ s.

As can be seen from Figure 12: write discharging condition along with the He ratio improves with writing the increase of voltage.But, as mentioned above, owing to the life-span when the He ratio surpasses 60% shortens greatly, so, be limited to 50% on the permissible He ratio.In other words, write voltage if increase, just need be used for the high-voltage driving circuit to the pulse of A electrode application voltage, this causes higher cost.Therefore, be necessary to reduce by the ratio that increases He and write voltage and reduce cost, the ratio of added He should be in that the life-span to PDP produces in the scope of adverse influence.

Figure 12 represents to contain the result of gained in the situation of 12% Xe by way of example, but is under 2%, 6%, 8%, 14% and 20% the situation in the Xe ratio, writes discharging condition also along with the He ratio with write the increase of voltage and improve.Therefore, for all above-mentioned Xe ratios, need be in the scope that can not have a negative impact reduce and write discharge voltage, and make the width τ a of the potential pulse that imposes on the A electrode elect 2 μ s or littler as by the ratio that increases He to the life-span of PDP.

More particularly, by in containing the discharge mist of 2% to 20% Xe, adding 15% to 50% He, and select the voltage pulse width that imposes on the A electrode as 2 μ s or littler as, guarantee that the stabilized driving of PDP and high brightness show.

Below, will the embodiment of imaging device of the present invention be described.Figure 13 is the block diagram of a kind of imaging system 104 of expression.Imaging device 102 (plasm display device) comprises a PDP100 and a drive circuit 101 that is used to drive PDP100.Imaging system 104 comprises an image source 103 that is used for image information is sent to imaging device 102.Imaging system itself can be a kind of traditional imaging system, in the detailed description of this omission to it.

By drive circuit 101 is linked to each other with PDP, constitute this imaging device, the discharge mist of the He that contains 62% Ne, 8% Xe and 30% is wherein arranged among the PDP, and the stagnation pressure of this discharge mist is made as 500 torrs.Image source 103 is used for picture signal is sent to imaging device, and it links to each other with imaging device, and then constitutes imaging system.Image to this imaging system is tested.Imaging system in this example has shown very high luminous efficiency, and instability occurs in the running, and guarantees that its life-span is long.

From above detailed description as can be known: the invention provides and a kind ofly have high-luminous-efficiency and guarantee that its life-span is long and drive stable PDP.And the present invention also provides a kind of PDP that can move under high brightness, high-resolution and low cost.Because luminous efficiency has increased, so the brightness height of brightness ratio traditional PD P of the present invention.In addition, the width of the potential pulse of the present invention by reducing to impose on the A electrode makes that writing discharge shortens and become possibility.By carrying out such operation, can increase the quantity of discharge cell to writing discharge.Therefore, the present invention can provide and have high-resolution PDP.And, because the present invention can guarantee high luminous efficiency by utilizing lower continuous discharge voltage, can be so the invention provides with the PDP of lower operation cost.

The invention provides the luminous efficiency with improvement, the PDP that guarantees long-life and stable operation.

Use plasm display device of the present invention, provide a kind of can be with the imaging system of high brightness and long-life stable operation.

Claims (46)

1. plasma display panel comprises:

Discharge sustaining electrode is right;

Towards the right addressing electrode of described discharge sustaining electrode;

Discharge space between described discharge sustaining electrode pair and described addressing electrode is filled with the discharge gas mixture that contains Xe, Ne and He at least in the described discharge space; And

Produce the circuit of writing discharge thereby be used for applying potential pulse at described discharge space to described addressing electrode,

Wherein: in the described discharge gas mixture ratio of Xe in the scope of 2%-20%,

The ratio of He is in the scope of 15%-50% in the described discharge gas mixture,

The ratio of described He is greater than the ratio of described Xe,

The stagnation pressure of described discharge gas mixture in the scope of 400 torrs-550 torr,

The width of described potential pulse is less than or equal to 2 μ s, and

Described potential pulse is rectangular pulse basically in writing discharge cycle.

2. according to the plasma display panel of claim 1, the voltage that wherein is used to write discharge is less than or equal to 70V.

3. according to the plasma display panel of claim 1, the voltage that wherein is used to write discharge is less than or equal to 65V.

4. according to the plasma display panel of claim 1, the voltage that wherein is used to write discharge is less than or equal to 60V.

5. according to the plasma display panel of claim 1, the voltage that wherein is used to write discharge is less than or equal to 55V.

6. imaging device comprises according to the plasma display panel of claim 1 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

7. imaging device comprises according to the plasma display panel of claim 2 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

8. imaging device comprises according to the plasma display panel of claim 3 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

9. imaging device comprises according to the plasma display panel of claim 4 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

10. imaging device comprises according to the plasma display panel of claim 5 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

11. a plasma display panel comprises:

Discharge space is filled with the discharge gas mixture that is made of Xe, Ne and He in the described discharge space;

A plurality of sparking electrodes comprise the electrode with addressing function; And

Thereby be used for producing the circuit of writing discharge at described discharge space to described electrode application voltage pulse with addressing function,

Wherein: in the described discharge gas mixture ratio of Xe in the scope of 2%-20%,

The ratio of He is in the scope of 15%-50% in the described discharge gas mixture, and the ratio of described He is greater than the ratio of described Xe,

The width of described potential pulse is less than or equal to 2 μ s, and

The stagnation pressure of described discharge gas mixture is in the scope of 400 torrs-550 torr.

12. according to the plasma display panel of claim 11, the ratio of Xe is in the scope of 2%-14% in the wherein said discharge gas mixture.

13. according to the plasma display panel of claim 11, the ratio of Xe is in the scope of 6%-14% in the wherein said discharge gas mixture.

14. according to the plasma display panel of claim 11, the ratio of Xe is in the scope of 6%-12% in the wherein said discharge gas mixture.

15. according to the plasma display panel of claim 11, wherein said potential pulse is rectangular pulse basically in writing discharge cycle.

16. according to the plasma display panel of claim 11, the voltage that wherein is used to write discharge is less than or equal to 70V.

17. according to the plasma display panel of claim 11, the voltage that wherein is used to write discharge is less than or equal to 65V.

18. according to the plasma display panel of claim 12, the voltage that wherein is used to write discharge is less than or equal to 60V.

19. according to the plasma display panel of claim 13, the voltage that wherein is used to write discharge is less than or equal to 55V.

20. an imaging device comprises according to the plasma display panel of claim 11 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

21. an imaging device comprises according to the plasma display panel of claim 12 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

22. an imaging device comprises according to the plasma display panel of claim 13 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

23. an imaging device comprises according to the plasma display panel of claim 14 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

24. an imaging device comprises according to the plasma display panel of claim 15 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

25. an imaging device comprises according to the plasma display panel of claim 16 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

26. an imaging device comprises according to the plasma display panel of claim 17 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

27. an imaging device comprises according to the plasma display panel of claim 18 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

28. an imaging device comprises according to the plasma display panel of claim 19 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

29. a plasma display panel comprises:

Discharge sustaining electrode is right;

Towards the right addressing electrode of described discharge sustaining electrode;

Discharge space between described discharge sustaining electrode pair and described addressing electrode is filled with the discharge gas mixture that is made of Xe, Ne and He in the described discharge space; And

Produce the circuit of writing discharge thereby be used for applying potential pulse at described discharge space to described addressing electrode,

Wherein: in the described discharge gas mixture ratio of Xe in the scope of 2%-20%,

The ratio of He is in the scope of 15%-50% in the described discharge gas mixture, and the ratio of described He is greater than the ratio of described Xe,

The width of described potential pulse is less than or equal to 2 μ s, and

The stagnation pressure of described discharge gas mixture is in the scope of 400 torrs-550 torr.

30. according to the plasma display panel of claim 29, the ratio of Xe is in the scope of 2%-14% in the wherein said discharge gas mixture.

31. according to the plasma display panel of claim 29, the ratio of Xe is in the scope of 6%-14% in the wherein said discharge gas mixture.

32. according to the plasma display panel of claim 29, the ratio of Xe is in the scope of 6%-12% in the wherein said discharge gas mixture.

33. according to the plasma display panel of claim 29, wherein said potential pulse is rectangular pulse basically in writing discharge cycle.

34. according to the plasma display panel of claim 29, the voltage that wherein is used to write discharge is less than or equal to 70V.

35. according to the plasma display panel of claim 29, the voltage that wherein is used to write discharge is less than or equal to 65V.

36. according to the plasma display panel of claim 29, the voltage that wherein is used to write discharge is less than or equal to 60V.

37. according to the plasma display panel of claim 29, the voltage that wherein is used to write discharge is less than or equal to 55V.

38. an imaging device comprises according to the plasma display panel of claim 29 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

39. an imaging device comprises according to the plasma display panel of claim 30 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

40. an imaging device comprises according to the plasma display panel of claim 31 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

41. an imaging device comprises according to the plasma display panel of claim 32 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

42. an imaging device comprises according to the plasma display panel of claim 33 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

43. an imaging device comprises according to the plasma display panel of claim 34 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

44. an imaging device comprises according to the plasma display panel of claim 35 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

45. an imaging device comprises according to the plasma display panel of claim 36 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

46. an imaging device comprises according to the plasma display panel of claim 37 and is used to drive the drive circuit of described plasma display panel that described drive circuit comprises control circuit at least.

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